Assistive sample collection and storage assembly

ABSTRACT

An assistive sample collection and storage assembly for collecting, transferring and storing a biological sample includes a sample collection device having a first portion and a second portion. The first portion is configured to receive a sample collection member. The assembly includes a sample storage device comprising a sample substrate to receive at least a portion of the biological sample from the sample collection member. The assembly is configured to exist in a first and second state. The sample collection member is disposed at a determined distance from the sample substrate in the first state. At least a portion of the sample collection member is in physical contact with at least a portion of the sample substrate in the second state. The sample collection member is configured to apply a determined amount of contact force between the collection member and the sample substrate in the second state of the assembly.

This is a division of U.S. patent application Ser. No. 14/035,085, filedSep. 24, 2013, now co-pending, the entire disclosure of which isincorporated herein by reference.

This invention was made with Government support under grant numberHR0011-11-C-0127 awarded by the Defense Advanced Research ProjectsAgency (DARPA). The Government has certain rights in the invention.

BACKGROUND

The invention relates to collection and storage of biological samples,and more particularly to devices configured to collect, transfer andstore the biological samples.

The collection of biological samples (such as blood) and extracting DNAfor genetic analysis from the sample have been widely used by theforensics and medical community for identification purposes such as, butnot limited to, paternity testing, genetic diagnostic testing in newborn screening programs, genetic typing for predisposition to aparticular disease, and genetic characterization for drugsusceptibility. Typically, collected biological samples are stored in adried state on an absorbant material. By way of example, dried bloodspots are commonly stored on substrates.

Typically, for sample storage of the biological samples, it is desirableto use substrates that facilitate efficient and reproducible transfer ofthe collected samples to a substrate card. However, typically, thesuccess of the transfer of the collected samples depends on skills ofthe user. Accordingly, the sample transfer process is adversely affectedin point-of-care type settings where the person (e.g., a nurse, or apatient) collecting the sample may have inadequate training in thesample collection and transfer. Moreover, when compared to othersamples, such as substrate based samples, the sample transfer successrate is relatively lower for swabbed samples (such as a buccal swab,nasal swab, or swab of a wound area) as the user needs to apply thesample to the correct location for sample collection and use the rightamount of force to transfer the sample from the swab to the samplesubstrate. For example, if less than a desirable force is applied totransfer the sample from the swab to the sample substrate, the samplemay not be efficiently transferred to the sample substrate. On the otherhand, if the force applied to the swab is more than the desirable force,the storage substrate may suffer damages.

BRIEF DESCRIPTION

In one embodiment, an assistive sample collection and storage assemblyfor collecting, transferring and storing a biological sample isprovided. The assembly includes a sample collection device and a samplestorage device. The sample collection device includes a first portionand a second portion, where the first portion of the sample collectiondevice is configured to receive a sample collection member, wherein thesecond portion is connected to the first portion by a rotating element.Further, the sample collection device is configured to rotate the samplecollection member about a longitudinal axis of the sample collectionmember. The sample storage device includes a sample substrate configuredto receive at least a portion of the biological sample from the samplecollection member. The assembly is configured to exist in a first stateand a second state. In the first state of the assembly, the samplecollection member is disposed at a determined distance from the samplesubstrate. Whereas, in the second state, at least a portion of thesample collection member is in physical contact with at least a portionof the sample substrate. Moreover, in the second state, the samplecollection member is configured to apply a determined amount of contactforce between the sample collection member and the sample substrate.

In another embodiment, an assistive sample collection and storageassembly for collecting, transferring and storing a biological sample isprovided. The assembly includes a sample collection device and a samplestorage device. The sample collection device includes a first portionand a second portion. The first portion of the sample collection deviceincludes a sample collection member having a handle. The second portionof the sample collection device is configured to be coupled to the firstportion and the sample storage device.

In yet another embodiment, a method for collecting, transferring andstoring a biological sample using an assistive sample collection andstorage assembly is provided. The method includes providing a samplecollection member, collecting the sample using the sample collectionmember. Further, the method includes providing a sample storage devicehaving a sample substrate, and providing the assistive sample collectionand storage assembly comprising the sample collection device and thesample storage device. Moreover, the method includes switching a stateof the assistive sample collection and storage assembly such that atleast a portion of the sample collection member is in physical contactwith at least a portion of the sample substrate, where the samplecollection member is in physical contact with the sample substrate at adetermined angle. Moreover, the method includes rotating the samplecollection member to facilitate transfer of at least a portion of thesample from the sample collection member to the sample substrate.

DRAWINGS

These and other elements and aspects of embodiments of the presentdisclosure will become better understood when the following detaileddescription is read with reference to the accompanying drawings in whichlike characters represent like parts throughout the drawings, wherein:

FIG. 1 is a perspective view of an example assistive sample collectionand storage assembly, in accordance with aspects of the presentdisclosure:

FIG. 2 is a perspective view of the example assistive sample collectionand storage assembly of FIG. 1 in a first state, where a samplecollection member is disposed at a distance from a sample substrate:

FIG. 3 is a perspective view of the example assistive sample collectionand storage assembly of FIG. 1 in a second state, where at least aportion of a sample collection member is in physical contact with atleast a portion of a sample substrate;

FIG. 4 is a block diagram of an example method of using an assistivesample collection and storage assembly for collecting, transferring andstoring a biological sample, in accordance with aspects of the presentdisclosure:

FIG. 5 is a perspective view of a first portion of a sample collectiondevice in use, in accordance with aspects of the present disclosure;

FIG. 6 is a perspective view of the first portion of the sample deviceof FIG. 5;

FIG. 7 is an exploded view of an assistive sample collection and storageassembly, in accordance with aspects of the present disclosure;

FIG. 8 is a perspective view of the assistive sample collection andstorage assembly of FIG. 7 in a first state:

FIG. 9 is a perspective view of the assistive sample collection andstorage assembly of FIGS. 7-8 in a second state:

FIGS. 10(a)-10(b) are cross-sectional views of an experimental set-upconfigured to assess an effect of a bending angle of a swab on alocation and amount of sample transferred on a sample substrate, inaccordance with aspects of the present disclosure; and

FIG. 11 is a schematic representation of overlapping images of a sampletransferred from a swab to a sample substrate.

DETAILED DESCRIPTION

Embodiments relate to assistive sample collection assemblies configuredto assist in collection, transfer and storage of a biological sample ina controlled manner. By way of example, the assistive sample collectionassemblies are configured to transfer the biological sample to adesirable location on a sample substrate in a reproducible manner. Itshould be noted that the terms “sample” and “biological sample” may beused interchangeably throughout the application. In certain embodiments,the assistive sample collection and storage assembly may be used tocollect degradable biologically sourced analytes such as nucleic acids,proteins, and respective fragments thereof. Non-limiting examples of thebiological sample may include saliva, blood, serum, lymph fluids, buccalcells, mucosal cells, cerebrospinal fluid, semen, feces, plasma, urine,a suspension of cells, or a suspension of cells and viruses. Inaddition, the biological samples may include samples from flora andfauna. In a non-limiting example, the biological samples may includeplant or fungal samples for the study of population genetics. Also, inone example, the assembly may be used for collection of the biologicalsamples for purposes, such as, but not limited to, collection of buccalcell samples for criminal databases, collection of crime scene samples(i.e., rehydrated blood, semen, saliva and liquid samples of the same);collection of sexual assault samples; collection of buccal samples forpopulation genetics or pharmacogenomics studies; collection of nasalsamples for respiratory infection diagnosis; collection of bacterial orparasite samples from food sources; collection of blood from meat at aslaughterhouse for meat traceability; or collection of biologicalsamples from animals for veterinary diagnostics. It should be noted thatat the time of collection, the biological samples may or may not existin a biological body from where the sample originated. By way ofexample, the biological sample may include a blood sample splattered ona floor of a crime scene.

In certain embodiments, the assistive sample collection and storageassembly may include a sample collection device and a sample storagedevice. As used herein, the terms “assistive sample collection andstorage assembly,” “assistive assembly,” and “assembly” may be usedinterchangeably. The sample collection device is configured to receiveat least one sample collection member. The sample collection member isconfigured to collect a biological sample. In some embodiments, thesample collection member may include an analyte collection surface. Theanalyte collection surface may include an analyte collection medium. Incertain embodiments, the sample collection member may be disposedoutside the sample collection device while collecting the sample. Inthese embodiments, the sample collection member is coupled to the samplecollection device after collecting the sample. In certain otherembodiments, the sample collection member may be disposed, at least inpart, in the sample collection device while collecting the sample. Thesample storage device includes a sample substrate. The sample substratemay be configured to receive and store the sample from the samplecollection member.

For analysis of the biological sample, the sample collection device andthe sample storage device are operated so as to transfer at least aportion of the sample from the sample collection member to the samplestorage device. By way of example, the sample collection devicecontaining a sample collection member is coupled to a sample storagedevice such that a portion of the sample collection member having thesample is brought in physical contact with a portion of the samplestorage device to facilitate the transfer of the sample from the samplecollection member to the sample storage device.

In one embodiment, the sample collection device may be releasablycoupled to the sample storage device. By way of example, the samplecollection device may be releasably coupled to the sample storage deviceat least during transfer of at least a portion of the sample from thesample collection member to the sample storage device. In one example,the sample substrate may be configured to receive the sample from thesample collection member upon physical contact between the samplecollection member of the sample collection device and the samplesubstrate of the sample storage device. The portion of the sampletransferred from the sample collection member to the sample storagedevice may be stored on the sample substrate. In certain embodiments,the sample storage device may include a storage medium suitable forcollecting and storing the biological sample. The storage medium may bedisposed on a surface of the sample substrate of the sample storagedevice. In some embodiments, a surface of the sample substrate may be avolume of a foam pad, for example, and not just a contact surface areaof the sample substrate. As used herein, the phrase “store the sample”or “storing the sample” may encompass the steps of disposing the sampleon the sample substrate and drying the sample.

One or more parts of the assistive sample collection and storageassembly may be configured for one time use to reduce or preventcontamination or spreading of infection via the sample collection andstorage assembly. In one example, the sample collection device may be adisposable device. In some embodiments, the design of the assistivesample collection and storage assembly facilitates collection, transferand storage of the sample, while preventing any undesirable contact ofthe user with the sample while transferring the sample from the samplecollection member to the sample storage device, or while storing thesample. Advantageously, in some embodiments, the assistive samplecollection and storage assembly may be configured to receive off-theshelf sample collection members, such as, but not limited to, swabs, forcollection of the biological samples. Furthermore, the assembly may beused by any person, including a patient, and may not necessarily need atechnician or skilled operator to collect, transfer or store the sample.In certain embodiments, the assistive sample collection and storageassembly may be configured for consistent and reproducible collection,transfer and storage of biological samples. In certain embodiments, apercentage of the biological sample transferred from the samplecollection member to the sample storage device may be reproducible. Incertain embodiments, the position of biological sample on the samplesubstrate transferred from the sample collection member to the samplestorage device is reproducible.

In certain embodiments, for analysis of the biological sample aftercollection, a suitable storage medium may be selected so as to remove atleast a portion of a biologically sourced analyte present on the storagemedium. Non-limiting examples of suitable storage media may includecellulose, such as #903® brand paper (GE Healthcare) or chemicallyimpregnated celluloses, such as FTA® and FTA® Elute brand paper (alsofrom GE Healthcare). These storage media provide a simple method forcollection, shipping and storage of biological samples. These storagemedia also contain chemistries which facilitate easy isolation of DNAfrom complex samples such as blood. Samples collected on treated oruntreated storage media are dried for storage and can be stored at roomtemperature for long periods of time.

Moreover, in some embodiments, the storage media may include at leastone stabilizing reagent that preserves at least one biological sampleanalyte for transport or storage. Non-limiting examples of suitablereagents for the storage media may include one or more of a weak base, achelating agent, and, optionally, uric acid or a urate salt or simplythe addition of a chaotropic salt, alone or in combination with asurfactant. In one embodiment, the storage media may have a visualdelineation disposed around the transfer area of the storage medium suchthat, if the sample storage device is removed from the sample collectiondevice, an operator may know where the material was deposited withoutreference to the device.

Furthermore, in certain embodiments, the assistive sample collection andstorage assembly may use a dry solid storage and transfer medium and amethod for the collection of biological material of interest (genetic orproteinaceous material) in a form suitable for storage and/or subsequentanalysis. The analyte collection surface may include an analytecollection medium suitable for collecting the sample.

In one embodiment, the sample collection member may be pre-fitted in thesample collection device. By way of example, the sample collectionmember may be a factory fit in the sample collection device. In analternative embodiment, the sample collection member may be availableseparately, and may be coupled to the sample collection device asrequired. Also, In one embodiment, the sample collection member may beused to collect the sample prior to being coupled to the samplecollection device. In another embodiment, the sample collection membermay be coupled to the sample collection device before collecting thesample. Non-limiting examples of the sample collection member mayinclude a flocked swab, cotton-tipped applicator, foam-tippedapplicator, or combinations thereof. In one example, the samplecollection member may include an off-the-shelf swab. In another example,the swab may be a customized swab that is designed to suit requirements(e.g., size, shape) of the user and the sample collection device.Non-limiting examples of the swab designs may include cylindrical swabsthat are symmetric about their longitudinal axis. However, other kindsof swabs, such as, but not limited to, non-symmetrical swabs (e.g., coneshaped swabs) may also be used.

Further, the sample collection device may include elements to disposethe sample collection member such that when the sample collection membercomes in physical contact with the surface of the sample substrate, alsoreferred to as “substrate surface”. The contact is at a desirable angleto facilitate transfer of the sample to the substrate surface. Inaddition, the sample collection device may be configured to providereproducible contact force between the sample collection member (e.g.,swab) and the sample substrate. Further, the sample collection devicemay be configured to provide a reproducible transfer location for thesample on the sample substrate. Moreover, the sample collection devicemay be configured to provide determined amount of collected samplevolume as well as sample concentration (sample volume per unit area ofthe sample substrate) that is compatible with downstream sample elutionand analysis. Furthermore, the sample collection device provides anergonomically suitable design to enable trained as well as untrainedusers to operate the device in a non-clinical setting. Advantageously,the sample collection device provides elements that facilitate storageof the sample while preventing user contact with the sample, or usercontact with the sample substrate to prevent the user from coming incontact with any hazardous chemicals or materials that are notbio-compatible.

In some embodiments, the sample collection device may include provisionsto be releasably coupled to the sample storage device. Thus, one canseparate the sample storage device from the collection device forsubsequent processing or storage. In one embodiment, a coupling elementbetween the sample collection device and the sample storage device maybe configured to allow for manual or automated release of the samplestorage device, but not allow for accidental loss of the sample storagedevice from the assembly.

In some embodiments, the assistive sample collection and storageassembly may have a monolithic structure. In some of these embodiments,the sample collection device and the sample storage device may form anintegrated structure. In some other embodiments, the assistive samplecollection and storage assembly may include two or more physicallyindependent portions. By way of example, the physically independentportions of the assembly may include a sample collection device and asample storage device. The sample collection device and sample storagedevice may be releasably or permanently coupled to one another to formthe assistive sample collection and storage assembly.

Further, in some embodiments, the sample collection device may have amonolithic structure. In some other embodiments, the sample collectiondevice may include two or more portions. In one embodiment, the two ormore portions of the sample collection device may be operatively coupledvia a coupling element. In one such embodiment, the coupling element maybe a flexure between the two or more portions of the sample collectiondevice. In one example, a first portion of the sample collection devicemay be releasably coupled to the second portion of the sample storagedevice. In another example, the first portion of the sample collectiondevice may be releasably coupled to the sample collection member.Non-limiting examples of the coupling element may include fasteners,such as, but not limited to, slots and pins.

The sample collection device may include provisions for a bi-statedesign of the assistive sample collection and storage assembly. In afirst state of the assembly, the sample collection member may bedisposed away from the sample substrate. More particularly, in the firststate of the assembly, the portion of the sample collection devicehaving the sample collection member and the other portion of the samplestorage device are locked such that the sample collection member isdisposed away from the sample substrate. In a second state of theassembly, the portion of the sample collection device having the samplecollection member and the other portion of the sample storage device arelocked such that at least a portion of the sample collection member isin physical contact with at least a portion of the sample substrate.

In certain embodiments, the sample collection device may include areceiver that is configured to receive the sample collection member. Thereceiver may be a snap-in element, a clip element, an adhesive basedelement, or any other design that is able to receive the samplecollection member (e.g., an off-the-shelf swab). The sample collectionmember may be permanently or releasably coupled to the receiver.

Additionally, in certain embodiments, an analyte collection surface ofthe sample collection member may include surfaces, such as, but notlimited to, a flocked surface. The analyte collection surface may bedimensioned and configured such that the volume of the sample beingtransferred from the sample collection member to the sample substrate iscontrolled. By controlling the volume of the transferred sample,overloading of any stabilizing reagents disposed on the storage mediumwith respect to the respective protecting capacity of the stabilizingreagents may be reduced or prevented. If used in nasal swabapplications, the analyte collection surface may be dimensioned andconfigured to fit within the human nasal cavity. Accordingly, when usedin buccal swab applications, the analyte collection surface should bedimensioned and configured to fit within the human mouth.

In some embodiments, for record keeping and traceability, the presentdevice may also include an identification label (such as conventionalbar coding). In one example, the identification label may be disposed onthe sample collection device and the sample storage device.

To ensure device integrity, in some embodiments, the assistive samplecollection and storage assembly may include a sterility envelopesurrounding device elements or devices of the assistive samplecollection and storage assembly. In some embodiments, the elements ordevices of the assistive sample collection and storage assembly may bemade from medical grade plastics. Additionally, the elements or devicesof the assistive sample collection and storage assembly may be free fromcontaminates and leachable materials (e.g., USP Class VI materials).Moreover, the elements or devices of the assistive sample collection andstorage assembly may be sterilized through conventional techniques suchas irradiation after the envelope is sealed. Kits may be made thatincorporate the above device along with any combination of associatedequipment or reagents including purification reagents, buffers, or thelike and storage systems, containers, or the like.

In one example embodiment, the assistive sample collection and storageassembly may include a sample collection member-bending approach. Inthis sample collection member-bending approach, a naturalstiffnessflexibility of a body of sample collection member may be usedto press a head of the sample collection member against the samplesubstrate to produce proper contact force and facilitate transfer of adesirable portion of the sample from the sample collection member to thesample substrate. In some embodiments, the user may rotate the samplecollection member (e.g., a swab) one or more times to facilitatephysical contact between the head of the sample collection member andthe sample substrate.

Advantageously, systems and methods described herein are configured toprovide and address one or more issues associated with reliablecollection, transfer, and storage of the biological sample on the samplesubstrate: 1) reproducible contact force between the sample collectionmember and the sample substrate 2) reproducible transferred samplelocation on the sample substrate, percentage of transferred volume andsample concentration (volume per unit area) to be compatible withdownstream sample elution and analysis; 3) ergonomically suitable toallow a wider range of users including untrained users in the field, ornon-clinical settings. 4) safe for the user to prevent undesirable usercontact with the sample substrate that may contain hazardous chemicals.

FIG. 1 illustrates an example assistive sample collection and storageassembly 10. The assembly 10 may include a sample collection device 12and a sample storage device 14. The assembly 10 may be configured toallow a trained or an untrained user to efficiently collect and store abiological sample. By way of example, the assistive sample collectionand storage assembly 10 may be configured to collect a biological sample(not shown) from the user, and successfully transfer and store adesirable volume of the collected sample in a desirable location of thesample storage device 14 with repeatability.

In the illustrated embodiment, the assistive sample collection andstorage assembly 10 is configured to collect the biological sample usinga sample collection member 16. Further, the assembly 10 is configured totransfer the collected biological sample from the sample collectionmember 16 to a sample substrate 18 of the sample storage device 14. Thesample substrate 18 is configured to chemically stabilize and store thebiological sample for further analysis. The design of the assistiveassembly 10 is configured to facilitate reproducible volume and locationof the sample on the substrate 18.

In some embodiments, the sample collection device 12 may have a firstportion 13 and a second portion 15 that are connected by a living hinge32. In one embodiment, the living hinge 32 is a thin flexible hinge or aflexure. In one example, the living hinge 32 may be made from the samematerial as the portions 13 and 15 of the sample collection device 12.Non-limiting examples of the material for the portions 13 and 15 mayinclude, plastic, metal, rubber, or combinations thereof. In oneembodiment, a sub-portion 24 of the first portion 13 may be a separatecomponent. In this embodiment, the sub-portion 24 may be configured tobe releasably or permanently coupled to the first portion 13. The livinghinge 32 may be configured to limit the relative rotational motionbetween the first portion 13 and second portion 15. Further, the livinghinge 32 is configured to provide fatigue resistance. In one example,the living hinge 32 may be injection molded. In another example, theentire assembly 10 including the sub-components may be injection molded.

The sample collection member 16 includes a head 20 and a body 22. In oneembodiment, the sample collection member 16 may be an off-the-shelfswab. In another embodiment, the sample collection member 16 may be acustomized swab. Moreover, in some embodiments, the sample collectionmember 16 may form an integral part of the sample collection device 12.In another embodiment, the sample collection member 16 may be aphysically separate entity from the sample collection device 12. In thisembodiment, the sample collection member 16 may be coupled or decoupledfrom the sample collection device 12, as needed. By way of example, thesample collection member 16 may be coupled to the sample collectiondevice 12 before collecting the sample. As illustrated, in someembodiments, the body 22 of the sample collection member 16 may bedisposed on fastener 26. The fastener 26 may have a determined height(h), generally represented by reference numeral 25. Further, thefasteners 26 and 30 may be configured to facilitate rotation of thesample collection member 16 along a longitudinal axis of the samplecollection member 16, represented generally by reference numeral 28. Thefasteners 26 and 30 are configured to hold the sample collection member16 while transferring the sample from the head 20 of the samplecollection member 16 to the sample substrate 18. The fasteners 26 and 30may be configured to permanently or releasably couple the samplecollection member 16 to the device 12. The fasteners 26 and 30 areconfigured to provide a desirable angle 33 to the swab 16 when the head20 of the sample collection member 16 is in contact with the samplesubstrate 18 for transfer of the sample. The height (h) 25 of thefastener 26 may be determined based on an angular value that isdesirable for the angle 33. Additionally, the fastener 31 is configuredto secure the head 20 of the sample collection member 16, therebypreventing the head 20 of the sample collection member 16 from movingalong the plane of the sample substrate 18, during transfer of thesample. Non-limiting examples of the fasteners 26, 30 and 31 may includeclasps, holders, ties, closures, snaps, pins, clips, toggles, orcombinations thereof. The fasteners 26 and 30 may employ similar ordifferent types of fastening means. In one embodiment, the fasteners 26,30 and 31 may be an integral part of the sample collection device 12.The fasteners 26, 30 and 31 may be configured to limit the translationalmotion of the sample collection member 16, where the translationalmotion is generally represented by reference numeral 27. Further, thefasteners 26, 30 and 31 are configured to allow rotation of the samplecollection member 16, as represented by reference numeral 29. Moreover,the fasteners 26 and 30 are configured to hold and bend the samplecollection member 16 to an optimal angle 33 for applying force at thehead 20 of the sample collection member 16 to facilitate transfer of thebiological sample from the sample collection member 16 to the samplesubstrate 18.

In a non-limiting example, the detent elements 34, 36 and the livinghinge 32 enable a bi-state operation of the sample collection andstorage assembly 10. By way of example, as illustrated in FIG. 2, thedetent elements 34, 36 and the living hinge 32 enable the assembly 10 toexist in the first state by allowing the sample collection member 16 tobe disposed away from the sample substrate 18. Further, as illustratedin FIG. 3, the detent elements 34, 36 and the living hinge 32 enable theassembly 10 to exist in the second state by allowing the samplecollection member 16 to be in physical contact with a surface of thesample substrate 18 at a desirable angle 33 to facilitate the transferof the sample from the sample collection member 16 to the samplesubstrate 18 in the second state of the assembly 10. The samplecollection and storage assembly 10 is configured to switchably changebetween the first and second states.

FIGS. 2-3 provide detailed views of detent elements employed in theassistive sample collection device 12 which enables the bi-stateoperation of sample collection and storage assembly 10 of FIG. 1. FIG. 2illustrates an embodiment 40 of the assistive assembly 10 of FIG. 1,where the sample collection device 12 and the sample storage device 14are in the first state of the bi-state design of the assembly 10. Anenlarged view of the detent mechanism is represented by referencenumeral 42. In the illustrated embodiment of FIG. 2, the detentmechanism 42 of the assembly 10 enables the assembly 10 to be in thefirst state, where the head 20 of the sample collection member 16 isdisposed away from the sample substrate 18. To maintain the first statethe device 12, a detent element 34 on the sub-portion 24 of the firstportion 13 is configured to interfere with a detent element 36 having abase 38. In one embodiment, the interference between the detent element36 and 34 retains the sample collection member 16 away from the samplesubstrate 18. The living hinge 32 is flexed such that the detent element36 is brought in physical contact with the detent element 34.

FIG. 3 illustrates the assembly 10 in the second state of the bi-statedesign of the assembly 10. In the illustrated embodiment, an exampledetent mechanism is illustrated by reference numeral 46. The detentmechanism 46 of the assembly 10 enables the assembly 10 to be in thesecond state. The detent element 36 and 34 are in a locked position toconfigure the sample collection member 16 to make physical contact witha surface of the sample substrate 18. In the second state, at least aportion of the sample collected by the sample collection member 16 maybe transferred to the sample substrate 18. In the illustrated embodimentof FIG. 3, the second state is obtained when the detent element 34 restsbelow an overhanging portion of the detent element 36. The detentelement 36 is configured to bend without breaking as the tab 34 isrotated towards the base 38 of the detent element 36. In one example, auser holding the first and second portions 13 and 15 of the samplecollection device 12 may rotate the two portions 13 and 15 relative toone another to obtain the second state of the assembly 10. In the secondstate of the assembly 10, the sample collection member 16 maintainsphysical contact with the sample substrate 18. In one embodiment, in thesecond state, the sample collection member 16 may be configured tomaintain physical contact with the sample substrate 18 without using anyexternal loads or pressure.

In the illustrated embodiment, the sample collection member 16 isconfigured to apply a determined amount of force on the sample substrate18 to facilitate transfer of at least a portion of the sample from thesample collection member 16 to the sample substrate 18. In theillustrated embodiment, the arrow 29 illustrates the rotational movementof the sample collection member 16 around the axis 28 to facilitatetransfer of the sample from the sample collection member 16 to thesample substrate 18. In certain embodiments, an optimal bending angle 33for the sample collection member 16 may be in a range from about 5degrees to about 35 degrees. The heights of the fasteners 26, 30 and 31may be selected to provide the optimal angle to the sample collectionmember 16 to facilitate transfer of the sample from the samplecollection member 16 to the sample substrate 18.

After transfer of the sample, the devices 12 and 14 may be decoupled. Insome embodiments, the devices 12 and 14 may be decoupled while theassembly 10 is still in the second state. In alternative embodiments,the devices 12 and 14 may be decoupled after switching the assembly 10from the second state to the first state. In some of these embodiments,the head 20 of the sample collection member 16 may be positioned awayfrom the sample substrate 18 to prevent any undesirable transfer of thesample from the sample collection member 18 to the sample substrate 18during decoupling of the sample storage device 14 from the samplecollection device 12. Further, positioning the head 20 away from thesample substrate 18 prevents any undesirable contact of the head 20 witheither the sample substrate 18 or any other part of the assembly 10. Inone example, the head 20 of the sample collection member 18 may bepositioned away from the sample substrate 18 by the user by rotating thetwo portions 13 and 15 relative to one another to obtain the secondstate.

FIG. 4 is an example flow chart 60 for a method for collecting,transferring and storing a biological sample using an assistive samplecollection and storage assembly 10 (see FIG. 1) of the presentdisclosure. The method of FIG. 4 will be described with reference toassistive assembly of FIGS. 1-3 and 5-9. At block 62, the methodcommences by collecting a biological sample. In a non-limiting example,the sample may be collected from a patient, a criminal suspect, avictim, a scene of crime, a plant, a fungus. In one embodiment, the userof the assembly may be a trained technician, in an alternativeembodiment, the user of the assembly may be a person who is not atrained technician. In one embodiment, the sample collection member maybe disposed in the sample collection device while collecting the sample.In another embodiment, the sample may be collected using the samplecollection member, and subsequently, the sample collection member may becoupled to the sample collection device to facilitate transfer of atleast a portion of the sample from the sample collection member to thesample substrate. In one example, the sample collection member may becoupled to the sample collection device using a snap-in mechanism.However, as will be appreciated, other fastening mechanisms, such asclipping, adhesive, and the like may also be used to couple the samplecollection member to the sample collection device. In one example, auser may use an off-the-shelf swab to collect the sample.

In some embodiments, the sample collection device may be available intwo or more portions. In these embodiments, one of the portions of thesample collection device may be coupled to the sample collection memberto collect the sample. The sample collection member may be pre-fitted inthe portion. Alternatively, the sample collection member may be coupledto the portion of the sample collection time at the time of use.

In addition, at block 66, the sample collection and storage assembly isprovided. The sample collection and storage assembly may be provided ina first state. In some embodiments, the step of providing the assistivesample collection and storage assembly includes coupling the samplecollection member to the sample collection device after collecting thesample. In these embodiments, the sample collection device and thesample storage devices may be already coupled to each other at the timeof sample collection.

In other embodiments, the step of providing the assistive samplecollection and storage assembly includes releasably coupling the samplecollection device having the sample collection member to the samplestorage device. In these embodiments, the sample collection member maybe already coupled to the sample collection device at the time of samplecollection.

It should be noted that in embodiments where the assistive samplecollection and storage assembly has a monolithic structure, the step ofproviding the assembly may be redundant.

Furthermore, at block 68, the state of the assistive sample collectionand storage assembly may be switched from the first state to a secondstate to provide physical contact between the sample collection memberand the sample substrate. The fasteners may be used to preventundesirable movements of the sample collection member in the secondstate of the assembly. In particular, fasteners may be used to preventundesirable movements of the sample collection member during transfer ofthe sample from the sample collection member to the sample substrate.

At block 70, at least a portion of the sample is transferred from thesample collection member to the sample substrate. In one embodiment, thesample may be transferred by applying force on the sample collectionmember such that the head of the sample collection member is pressedagainst the sample substrate, and at least a portion of the sample istransferred to the sample substrate. In one embodiment, the head of thesample collection member may be rotated along a longitudinal axis of thesample collection member one or more times to ensure that sample istransferred from the surface area of the head of the sample collectionmember. The sample from the head of the sample collection member may betransferred to the substrate by applying a force on the head of thesample collection member.

Moreover, at block 72, subsequent to the transfer of the sample, thesample collection device is decoupled from the sample storage device. Itshould be noted that optionally, after transfer of the sample, but priorto decoupling of the sample collection and sample storage devices, thesample collection device may be returned to the first state prior todecoupling the devices. In certain embodiments, the assistive samplecollection and storage assembly may be made using one or more of rapidprototyping, molding, casting, injection molding, machining, orcombinations thereof.

FIG. 5 illustrates an example embodiment 80 of a portion of an assistivesample collection and storage assembly, such as the assistive assemblyof FIG. 1, being used by a user 84 to collect a nasal sample. In theillustrated embodiment, the user 84 employs a first portion 82 of asample collection device (not shown) to collect the sample. In theillustrated embodiment, the first portion 82 of the sample collectiondevice is configured to receive a sample collection member 86 (e.g., anasal swab). In the illustrated embodiment, the sample collection member86 is embedded in a body 88 of the first portion 82. In one embodiment,the sample collection member 86 may be coupled to the first portion 82at the time of use, e.g., before and during collecting the sample. Inanother embodiment, the sample collection member 86 may be coupled tothe first portion 82 of the sample collection device after collection ofthe sample. The sample collection member 86 may be configured to besnapped into the first portion 82. Moreover, in one embodiment, thesample collection member 86 may be an off-the-shelf swab.

In the illustrated embodiment, the sample collection member 86 includesa handle 90. The handle 90 of the sample collection member 86 providesthe provision for holding the sample collection device. By way ofexample, at the time of sample collection, the user 84 may hold thesample collection member 86 using the handle 90. The sample collectionmember 86 may be rotated using the handle 90. As will be appreciated,rotation of the sample collection member 86 facilitates samplecollection.

FIG. 6 illustrates the first portion 82 of the sample collection device(not shown) and the sample collection member 86. The body 88 and handle90 of the sample collection member 86 include detent elements 91 and 92to track number of rotations of the sample collection member 86. Anenlarged view 96 shows detent elements 91 and 92. Additionally, the body88 of the first portion 82 includes a second detent element 94configured to achieve a bi-state design of the assembly.

The detent elements 91 and 92 provide a feedback to the user regardingthe number of rotations of the sample collection member 86 that havebeen completed during collection or transfer of the sample. The feedbackmay be provided by using mechanical means to produce a tactilesensation, where the detent haptic feedback is provided at thecompletion of a rotation. In one example, the feedback from the detentelements 91 and 92, may be provided using an audible clicking sound fromthe detent elements 91 and 92, where the clicking sound is provided atthe completion of a rotation. In one embodiment, controlling the numberof rotations helps to improve reproducibility of the sample transfer.Further, the detent elements 91 and 92 also help prevent the user fromrotating less than one complete rotation, in which case some portion ofthe sample collection member 86 may not come in physical contact withthe sample substrate (not shown). Further, the detent elements 91 and 92may be provided in the first portion 82 to prevent the sample collectionmember 86 from undesirably rotating while collecting the sample (e.g.,mucus sample).

As illustrated in FIG. 6, the assembly may include elements that enhanceergonomics and user-friendliness of the assembly. In particular, thefirst portion 82 may be designed to provide the user with anergonomically suitable grip. By way of example, a size of element 90 ofthe sample collection member may be suitable for the user to holdelement 90 with the hand and rotate element 90 during sample collectionor transfer.

FIG. 7 illustrates an exploded view 100 of an assistive samplecollection and storage assembly employing the sample collection member86 (see FIG. 5) and first portion 82 of the sample collection device. Inoperation, subsequent to the collection of the sample by the firstportion 82 of the sample collection device, the first portion 82 may becoupled to a second portion 102 of the sample collection device to forma sample collection device. Further, a sample storage device 104 may becoupled to the second portion 102 of the sample collection device toform the assistive sample collection and storage assembly. The samplecollection device having the portions 82 and 102 may include one or morefasteners configured to couple the sample storage device 104 to thesample collection device. The fasteners may be configured to allow theassembly to switch between the first and second states. In oneembodiment, the first portion 82 may include a counterpart of thefasteners to facilitate coupling of the first portion 82 of the samplecollection device to the second portion 102 of the sample collectiondevice. Further, the second portion 102 of the sample collection devicemay include a detent element 107 corresponding to detent element 94.

Detent elements 94 and 107 having a double-detent design is configuredto achieve a bi-state design wherein the assembly is able to keep thesample collection member 86 away from the sample substrate until theuser snaps the device to bend the sample collection member 84 at theoptimal angle against the sample substrate. The detent element 107 maybe moved within the detent element 94 to enable the switch between thefirst and second states of the assembly. Also, fasteners 105 and 109 maybe used to couple the portions 82 and 102 of the sample collectiondevice.

FIG. 8 illustrates a first state of an assistive sample collection andstorage assembly 106 or a sample collection device 108. The assembly 106includes the sample collection device 108 and the sample storage device104. In the first state, the portions 82 and 102 of the samplecollection device 108 are disposed such that a head 110 of the samplecollection member 86 is disposed at a distance from a sample substrate112 of the sample storage device 104.

The assistive sample collection and storage assembly 106 is configuredto exist in two discrete states that can be transitioned to one anotherby rotating the first portion 82 relative to the second portion 102 orthe sample storage device 104. In the first state, the portions 82 and102 of the sample collection device 108 are disposed such that the head110 of the sample collection member 86 is disposed at a distance from asample substrate 112 of the sample storage device 104.

Reference numeral 113 represents an enlarged view of the detent elements91 and 92. As illustrated in the enlarged view 113, the handle 90 of thesample collection member 86 includes detent element 91 and is configuredto rotate as generally represented by reference numeral 111. An enlargedview of detent elements 94 and 107 in the first state of the assistivesample collection and storage assembly 106 is represented generally byreference numeral 114.

FIG. 9 depicts an embodiment 115 of the assistive sample collection andstorage assembly. As illustrated in FIG. 9, in the second state, theportions 82 and 102 of the sample collection device 108 are disposedsuch that at least a portion of the head 110 of the sample collectionmember 86 is in direct physical contact with a portion of a surface ofthe sample substrate 112 of the sample storage device 104. In the secondstate, the sample collection member 86 is bent at an optimal angle withrespect to the second portion 102 or the sample storage device 104 tomaintain an optimal contact force between the head 110 of the samplecollection member 86 and the sample substrate 112 on the sample storagedevice 104. By rotating the sample collection member 86 using element 90of the sample collection member 86, at least a portion of the biologicalsample is transferred to the sample substrate 112 of the sample storagedevice 104. The sample may be transferred with reproducible location,percentage of transferred sample and sample concentration (volume perunit area). This transfer method is compatible with different types ofcollection members (e.g., swab) with an axially-symmetric head that cancollect a sample by rotation and a relatively flexible body. The deviceis designed to be easy to use and mistake-proof.

An enlarged view of the detent elements 94 and 107 in the second stateof the assistive sample collection and storage assembly 106 isrepresented generally by reference numeral 116. As illustrated, in thesecond state, the head 110 of the sample collection member 86 is inphysical contact with the sample substrate 112. The detent elements 94and 107 having a double-detent design is configured to achieve abi-state design. In particular, the detent element 107 disposed withinthe detent element 94 is able to switch between a first position asillustrated in the enlarged view 114 (FIG. 8), and the second positionas illustrated in the enlarged view 116. The shifting of the position ofthe detent element 107 occurs when a user snaps the first portion 82 tobend the sample collection member 86 at the optimal angle to the samplesubstrate 112.

In one embodiment, subsequent to the transfer of the sample, the detentelements 94 and 107 are configured in the first state, and the samplecollection device 108 is decoupled from the sample storage device 104.In another embodiment, subsequent to the transfer of the sample, thedetent element may be maintained in the second state, and the samplecollection device 108 is decoupled from the sample storage device 104.

In certain embodiments, the assembly utilizes the flexibility of thesample collection member to create desirable consistent contact force bybending/flexing the sample collection member at an optimal angle againstthe surface of the sample substrate. Further, one or more elements ofthe sample collection device may be configured to guide the head of thesample collection member and ensure that the head of the samplecollection member stays in the same desirable position during a sampletransfer. In addition to features and elements described herein above,the assistive sample collection and storage assembly may also includeone or more elements to prevent user mistakes, for example, a guide thatstops undesirable rotation of the sample collection member. The guidemay be configured to prevent the handle which includes the samplecollection member from rotating about the base, before the handle snapsonto the base. This snapping of the handle in the base preventspremature contact between the sample collection member and the samplesubstrate. With all these elements, the assistive sample collection andtransfer assembly becomes easier to use and mistake-proof. The assemblymay also include a cover that prevents undersirable finger contact withthe substrate and so forth. The assistive sample collection and transferassembly facilitates reproducible biological sample transfer in bothlocation and percentage of transferred volume from an off-the-shelf orcustomized swab to the sample substrate by a trained or novice userusing the assembly, while making the assembly mistake-proof.

Example 1

In one example, an arrangement 130 of an experimental set-up is providedto determine an optimal bending angle for a sample collection member,such as a swab. As illustrated in FIGS. 10(a)-10(b), the arrangement 130includes a peg board 140. A swab 142 is coupled to the peg board 140using c-clips 144 and 146. The number and positions of the clips 144 and146 may be varied on the peg board 140 to obtain different bendingangles 148 and 154 of the swab 142 to facilitate contact between theswab 142 and the sample substrate 150. Patterns 152 and 156 representpositions of the transferred sample on the sample substrate 150. Thepattern 152 corresponds to the position of the swab 142 as illustratedin FIG. 10(a). Similarly, the pattern 156 corresponds to the position ofthe swab 142 as illustrated in FIG. 10(b).

Sample transfer efficiency is analyzed quantitatively to determine theoptimal bending angle. The transfer efficiency is quantified by a volumeof sample in a 3 mm diameter sample area (the current sample isolationarea). Amount of sample transferred from the swab 142 on the samplesubstrate 150 is obtained by measuring a weight change of the samplesubstrate 150 before and after transfer of the sample. The optimalnumber of turns of the swab required to transfer a desirable amount ofthe sample is also determined with this arrangement by evaluating thetransfer efficiency and substrate damage.

The experimental procedure included disposing the swab in place andaligning the head of the swab at a desirable location on the substrate.In the illustrated embodiment of FIG. 11, the head of the swab isaligned with a hole on the peg board. Next, retaining rings areinstalled to prevent front and back movement of the swab. The weight ofthe swab and the substrate are measured. Furthermore, about 50 μL ofmucus sample is applied on an interior of a pipette using a syringe. Theswab is rolled against the interior of the pipette to transfer thesample on the swab. The swab with the mucus sample is weighed.Subsequently, the swab is disposed on the peg board. In addition, asuitable surface (e.g., a paper) is disposed on the substrate. Next, thepeg board and the substrate are arranged such that there is physicalcontact between the swab head and the substrate. While in contact withthe substrate, the swab is rotated ten times to facilitate transfer ofthe mucus sample from the swab head to the substrate. Subsequent to thetransfer of the sample, the swab and the substrate paper are releasedand weighed. FIG. 11 illustrates images of examples of the transferredsamples and the corresponding swab angles.

The transfer efficiency is quantified by the volume of mucus in a 3 mmcircle, which equals the amount of mucus that DNA/RNA can be eluted fromin the work flow. This can be obtained by measuring the weight change ofthe substrate before and after and the computing the mucus spot sizeusing image processing. The results are listed in Table 1. It isobserved that for a bending angle larger than the bending angle 148 ofFIG. 10(a), the transferred volume in a 3 mm² area does not increase asbending angle increases.

TABLE 1 S. No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Angle 0 4.7 9.5 14 18.422.6 26.6 5.8 10.5 15 19.1 21.5 24.2 26.8 (degrees) Vol. 1.08 1.63 1.841.75 1.90 1.72 1.73 1.52 1.61 1.48 1.71 1.63 1.64 1.67 per 3 mm² (μL)

An amount of food dye that is less than about 10 μL in 1.5 mL mucussample is used. A ETF31 base paper is used as a surface of thesubstrate. About 50 μL of mucus sample is used for each position of thebending angle of the swab. Further, two different locations for thefront c-clip (close to the swab head) and seven locations for the rearc-clip are evaluated. The swab is rotated for ten turns to transfer thesample from the swab to the substrate.

Initially, the swab is disposed parallel to a surface of the substrate,the bending angle of the swab at this stage may be considered to be zerodegrees. For bending angles of the swab above zero degrees, thetransferred volume in a 3 mm diameter area does not increase immediatelywith the increase in the bending angle in. However, bending anglesgreater than about 22.6 degrees (e.g., config. 6) may cause excessiveforce on the surface of the substrate, thereby damaging the substrate.Considering an amount of the transferred volume of the sample andsubstrate damage, an optimal bending angle in a range from about 5degrees to about 10 degrees is determined. An average volume of thesample transferred from the swab to the substrate in a 3 mm elution areais about 1.67 μL+0.21 μL. A position of the transferred sample on thesubstrate is analyzed using image processing. A center position of thetransferred sample relative to the peg board has deviation of up toabout 0.8 mm in both horizontal and vertical directions (represented byx- and y-axes, respectively). The arrangement demonstratedreproducibility in the volume of the sample transferred and location ofthe sample on the substrate.

Example 2

A volume of the biological sample transferred from the substrate wasobtained by measuring a weight of the substrate before and after thetransfer of the biological sample.

The position of the transferred mucus spot was analyzed using imageprocessing in Matlab. A schematic of an overlapped image 160 of alltransferred samples 162 is shown in FIG. 11. A darker area 164 indicatesthe common area shared by all the mucus samples. The darker area 164covers the interior 3 mm² compression seal 166, which is shown as thecircle. One can wrap a rectangle around the sample with the edgesparallel to the image edges. The center position of such rectanglereferenced to the corner of the peg booard is obtained for each sample.The results are shown in Table 2. Mucus spot positions after transfer.The center position has small standard deviation of 0.8 mm in bothhorizontal and vertical direction.

In the illustrated embodiment of FIG. 11, the transferred sample imagesare added together. The rings 164 indicate the compression seal. Theregion 166 indicates a common area shared by all samples.

Advantageously, the assembly is lightweight and compact in size. In oneexample, the assembly may weigh in a range from about 15 grams to about50 grams. Further, the assembly is injection moldable, without need forany further processing. Hence, the assembly may be manufactured at a lowcost. Moreover, the customized swab may also be manufactured in acost-effective fashion. In some embodiments, the device may be used in amulti-analyte point-of-care diagnostic platform that encompasses theentire sample collection to sample analysis workflow. The assemblyenables a method to transfer biological sample from a swab to substratepaper by bending a swab. Such a method of sample transfer is compatiblewith a variety of swabs and is applicable to a wide range of biologicalsamples. Further, the assembly is easy-to-use and mistake proof.Accordingly, the assembly may be used by users including untrainedpersons in clinical or non-clinical settings.

While only certain elements of the invention have been illustrated anddescribed herein, many modifications and changes will occur to thoseskilled in the art. It is, therefore, to be understood that the appendedclaims are intended to cover all such modifications and changes as fallwithin the scope of the invention.

1. A method for collecting a biological sample using an assistive samplecollection and storage assembly, comprising: providing a samplecollection member; collecting the sample using the sample collectionmember; providing a sample storage device comprising a sample substrate;providing an assistive sample collection and storage assembly comprisingthe sample collection device and the sample storage device; switching astate of the assistive sample collection and storage assembly to asecond state such that at least a portion of the sample collectionmember is in physical contact with at least a portion of the samplesubstrate; bending the sample collection member at an optimal angleagainst a surface of the sample substrate; applying a force at a head ofthe sample collection member to transfer the biological sample from thesample collection member to the surface of the sample substrate in thesecond state of the assembly; rotating the sample collection member tofacilitate transfer of at least a portion of the sample from the samplecollection member to the sample substrate; de-coupling the samplestorage device from the sample collection device; and storing thesample.
 2. The method of claim 1, wherein the step of providing anassistive sample collection and storage assembly comprises coupling thesample collection member to the sample collection device aftercollecting the sample.
 3. The method of claim 1, wherein the step ofproviding an assistive sample collection and storage assembly comprisesreleasably coupling the sample collection device having the samplecollection member to the sample storage device.
 4. The method of claim1, wherein the step of bending further comprises applying a determinedforce while rotating the sample collection member to facilitate transferof the sample.
 5. The method of claim 1, wherein the step of providingthe sample storage device comprises providing a stabilizing agent on thesurface of the sample substrate.
 6. The method of claim 4, furthercomprising rotating the sample collection member for a determined numberof turns.
 7. The method of claim 1, further comprising switching theassembly to the first state prior for decoupling the sample storagedevice from the sample collection device.